Optical quadrature Interferometer

ABSTRACT

An optical quadrature interferometer is presented. The optical quadrature interferometer uses a different state of polarization in each of two arms of the interferometer. A light beam is split into two beams by a beamsplitter, each beam directed to a respective arm of the interferometer. In one arm, the measurement arm, the light beam is directed through a linear polarizer and a quarter wave plate to produce circularly polarized light, and then to a target being measured. In the other arm, the reference arm, the light beam is not subject to any change in polarization. After the light beams have traversed their respective arms, the light beams are combined by a recombining beamsplitter. As such, upon the beams of each arm being recombined, a polarizing element is used to separate the combined light beam into two separate fields which are in quadrature with each other. An image processing algorithm can then obtain the in-phase and quadrature components of the signal in order to construct an image of the target based on the magnitude and phase of the recombined light beam. The system may further be used for lensless imaging.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. application Ser. No. 08/658,087, filed Jun. 4, 1996 now U.S. Pat. No. 5,883,717 issued Mar. 16, 1999. This application further claims priority under 35 U.S.C. §119(e) to provisional patent application Ser. No. 60/032,923 filed Dec. 6, 1996; the disclosure of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

Mach-Zender interferometers and Michelson interferometers are known in the art. The interferometers typically include a beamsplitter which divides a signal from a light source into two separate signals which are in-phase with one another. One signal is sent through a reference arm which may include a compensation element. The other signal is sent through a measurement arm, in which the optical signal is exposed to some change in amplitude and phase. In the Mach-Zender interferometer, after the signals have propagated through their respective reference and measurement arms, the signals are combined, whereas in the Michelson interferometer, after the signals have propagated through their respective arms they are reflected back through the arms again where they are then combined. The combined beams produce an interference pattern with bright and dark regions indicative of the phase of the signal beam relative to the reference. The dependence of the brightness of the interference pattern on the relative phase and amplitude is complicated. The interferometers are sensitive to noise, and the algorithms involved in performing the phase retrieval and comparisons are cumbersome, involving lengthy calculations and introducing errors.

BRIEF SUMMARY OF THE INVENTION

An optical quadrature interferometer according to the present invention includes a light source which may be polarized or an unpolarized light source and a polarizer, and a beamsplitter which splits the light provided by the light source into two signals which are in a defined phase relationship with each other. In one path a quarter wave plate is used to convert the polarization of the light to circular. This circularly polarized light can be represented by equal amounts of vertically and horizontally polarized light with a phase difference of 90° between them. The circularly polarized signal is then transmitted through a target and the resulting signal is combined with the reference signal. The combined signal is then directed through a polarizer which can switch between vertical polarization and horizontal polarization or alternatively through a polarizing beamsplitter. The combined signal can thus be separated into two separate fields which are in quadrature with each other. An image processing algorithm can then obtain the in-phase and quadrature information and provide detailed images of the amplitude and phase of the target.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a diagram of a prior art Mach-Zender type interferometer;

FIG. 2 is a diagram of a first implementation of an optical quadrature interferometer;

FIG. 2A is a diagram of the optical quadrature interferometer of FIG. 2 including an additional imaging system;

FIG. 2B is a diagram of the optical quadrature interferometer of FIG. 2A including an additional imaging system channel;

FIG. 3 is a diagram of a prior art Michelson type interferometer;

FIG. 4 is a diagram of an additional implementation of an optical quadrature interferometer;

FIG. 4A is a diagram of the optical quadrature interferometer of FIG. 4 including an additional imaging system;

FIG. 5 is a diagram of an optical quadrature interferometer including a double balanced imaging system; and

FIG. 5A is a diagram of an additional embodiment of an optical quadrature interferometer including a double balanced imaging system.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows a prior art Mach-Zender interferometer 10. This interferometer comprises a light source 20, such as a laser, providing a beam of light 80 which is directed to a beamsplitter 30. The beamsplitter 30 splits the beam of light 80 into two secondary beams 82 and 84 which are in phase with each other. The beamsplitter 30 is angled with respect to light source 20 such that the reflected beam is directed along an axis which is different than that of light beam 80. Although angles of approximately ninety degrees are shown in the Figures, it should be appreciated that any angle could be used. The first secondary beam 82 is the portion that passes through the beamsplitter 30. This first secondary beam 82 is directed to a first mirror 40, which is angled to reflect the first secondary light beam 82 along a different axis to a recombining beamsplitter 60. This path, from beamsplitter 30 to first mirror 40 then to recombining beamsplitter 60 comprises the reference arm 94, and provides for a beam unaffected by the target 90.

Second secondary beam 84 is the light beam reflected by the beamsplitter 30 which is angled such that the reflected light is directed to a second mirror 50. Second mirror 50 is angled such that the second secondary beam 84 is directed through a target 90. The second secondary beam 84 is subjected to a phase change by passing through target 90 resulting in measurement beam 85. This path from beamsplitter 30, to mirror 50, through target 90, to recombining beamsplitter 60 comprises the measurement arm 92.

First secondary beam 82 and measurement beam 85 are combined by recombining beamsplitter 60 to provide resulting beam 86. Recombining beamsplitter 60 is angled such that resulting beam 86 is directed to detector 70. Any difference in phase between first secondary beam 82 and measurement beam 85 can be determined by analysis of resulting beam 86 by detector 70. A phase retrieval algorithm is used to determine the density and optical thickness or other characteristics of the target 90.

Referring now to FIG. 2 a first implementation of an optical quadrature interferometer 100 is shown. The optical quadrature interferometer 100 is based on a Mach-Zender interferometer and comprises a light source 20, such as a laser, providing a beam of light 80 which is directed to a beamsplitter 30. When a light source 20 which is not well polarized is used, a polarizer 150 which polarizes the light at 45° to the vertical, may be inserted between the light source 20 and the beamsplitter 30. Other angles are also possible, provided that a corresponding change is made at the output. If a well polarized light source is used, polarizer 150 is not necessary. The beamsplitter 30 splits the beam of light 80 into two secondary beams 82 and 84 which are in phase with each other. The beamsplitter 30 is angled such that a portion of the beam 84 is reflected along a different axis than that of beam 80, and a portion of the beam 82 passes through the beamsplitter 30.

The portion of light reflected by beamsplitter 30 is the second secondary light beam 84. This beam is directed through a quarter wave plate 120 by second reflective element 50. The quarter wave plate 120 provides for a relative phase shift of Δφ=π/2 radians which is equivalent to a phase shift of 90° between horizontal and vertical components of phase shifted beam 81. Phase shifted beam 81 is then directed through target 90. As phase shifted beam 81 passes through target 90, phase shifted beam 81 may undergo a change in phase, amplitude or both, resulting in measurement beam 85. This path comprises the measurement arm 92.

The first secondary beam 82 is directed to a reference 110 which alters the phase of light beam 83 to nearly match that of beam 84. For example, if the target being measured was a test-tube of water containing a fiber to be measured, the compensation element would be a test-tube of water without the fiber, such that any phase or amplitude change resulting from the test-tube and water in the measurement arm is compensated for in the reference arm. Accordingly, the interference pattern will not contain high spatial-frequency components which would require very good spatial resolution. Compensated light beam 83 is directed to first reflective element 40. First reflective element 40 is angled to reflect the compensated beam 83 to an recombining beamsplitter 60. This path, from beamsplitter 30 through reference element 110, to first reflective element 40 and to recombining beamsplitter 60 comprises the reference arm 94.

Compensated light beam 83 and measurement beam 85 are combined by recombining beamsplitter 60 to provide resulting beam 86. Recombining beamsplitter 60 is angled such that resulting beam 86 is directed along a different axis than compensated light beam 83. Resulting beam 86 is directed through polarizer 140. Polarizer 140 is rotated between two positions, a first position where polarizer 140 is a horizontal polarizer, and a second position where polarizer 140 is a vertical polarizer. Polarizer 140 is used to separate the mixed polarization field of resulting beam 86 into two separate fields which are in quadrature with each other by rotating polarizer 140 between it's two positions. The beam resulting from polarizer 140 is directed to imaging system 75 which utilizes an image processing algorithm to obtain the in-phase and quadrature components of the signal, thereby providing interpretation of the data using both the magnitude and phase information.

The imaging system 75 may comprise a scattering screen such as ground glass or milk glass which is followed by a charge coupled device (CCD) camera or other television camera, and a computer system including a device for storing and retrieving image frames from the CCD camera. The imaging system may also comprise photographic film and an optical reconstruction system for producing holographic images from the processed film, or direct display on a CCD.

Referring now to FIG. 2A, an optical quadrature interferometer 150 is shown. This optical quadrature interferometer is similar to the one shown in FIG. 2 except that recombining beamsplitter 60 has been replaced with polarizing beamsplitter 65, polarizer 140 has been removed, and a dual channel imaging system 75 and 75' are implemented to provide interpretation of the data using both the phase and magnitude information. Resultant beam 86 is directed to polarizing beamsplitter 65 which provides for two polarized output beams 87 and 88. Each polarized output beam 87 and 88 is provided to a respective imaging system 75 and 75'.

Referring now to FIG. 2B, an optical quadrature interferometer 160 is shown. This optical quadrature interferometer is similar to the one shown in FIG. 2A and includes an additional polarizing beamsplitter 66, and an additional dual channel imaging system 76 and 76'. A second resultant beam 89 is also provided by recombining beamsplitter 60. While this second resultant beam 89 is ignored in other embodiments, it is utilized in this embodiment. Second resultant beam 89 is directed to second polarizing beamsplitter 66 which provides for two polarized output beams 91 and 92. Each polarized output beam 91 and 92 are provided to a respective imaging system 76 and 76', thus providing for a four channel imaging system.

Referring now to FIG. 3, a prior art Michelson interferometer 200 is shown. A light source 20, such as a laser, provides a beam of light 80 which is directed to a beamsplitter 30. The beamsplitter 30 splits the beam of light 80 into two secondary beams 82 and 84 which are in phase with each other. The first secondary beam 82 is the portion that passes through the beamsplitter 30. This light beam is directed to a first mirror 40, which is angled to deflect the first secondary light beam along the same axis back to the beamsplitter 30. This path is the reference arm 96, and provides for a beam unaffected by a target.

Second secondary beam 84 is the light beam reflected by the beamsplitter 30. Beamsplitter 30 is angled such that the reflected light is directed to a target 90 where secondary beam 84 undergoes a phase shift upon passing through target 90. The beam exiting target 90 is directed to second mirror 50. Second mirror 50 is angled so that the second secondary beam is directed back through the target 90. The second secondary beam is subjected to a second phase change by target 90. First secondary beam 82 and second secondary beam 84 are combined by beamsplitter 30 to provide resulting beam 86. Any difference in phase between first secondary beam 82 and second secondary beam 84 can be determined by analysis of resultant beam 86 by detector 70. A phase retrieval algorithm is used to determine the density, clarity or other characteristics of the target 90.

FIG. 4 shows an embodiment of an optical quadrature interferometer 250 based on a Michelson interferometer. The optical quadrature interferometer 250 comprises a light source 20, such as a laser, providing a beam of light 80 which is directed to a beamsplitter 30. An optional polarizer 150 which polarizes the light at 45° (or other suitable angle) to the vertical may be used if the light source 20 is not well polarized. The beamsplitter 30 splits the beam of light 80 into two secondary beams 82 and 84 which are in a known phase relationship with each other. The first secondary beam 82 is directed to a reference 110 resulting in compensated light beam 83. Compensated light beam 83 is then directed to a first reflective element 40. First reflective element 40 is oriented such that the compensated light beam is reflected back along the same axis, through reference 110, and to beamsplitter 30.

In the measurement arm 98 of the optical quadrature interferometer 250, the second secondary light beam 84 is directed through a one-eighth wave plate 130. The one-eighth wave plate 130 provides for a relative phase shift of Δφ=π/4 radians which is equivalent to a phase shift of 45° between the vertical and horizontal components of the beam entering the one-eighth wave plate 130. Beam 81 is then directed through target 90, where it undergoes a change in phase, amplitude or both; resulting in measurement beam 85. Measurement beam 85 is then directed to second reflective element 50 which is oriented so that beam 85 is reflected back through target 90, then through one-eighth wave plate 130, where the beam is phase shifted another 45°, resulting in the beam being shifted a total of 90° between the vertical and horizontal polarization components of the beam, not including any phase shift as a result of the beam passing through the target 90.

Compensated light beam 83 and measurement beam 85 are combined by beamsplitter 30 to provide resulting beam 86. Resulting beam 86 is then directed to polarizer 140 which is used to separate the mixed polarization field into two separate fields which are in quadrature with each other by rotating polarizer 140. Polarizer 140 is rotated between two positions, a first position where polarizer 140 is a horizontal polarizer, and a second position where polarizer 140 is a vertical polarizer. Polarizer 140 is used to separate the mixed polarization field of resulting beam 86 into two separate fields which are in quadrature with each other by rotating polarizer 140 between it's two positions. The beam resulting from polarizer 140 is directed to imaging system 75 which uses an image processing algorithm to obtain the in-phase and quadrature components of the signal, thereby providing interpretation of the data using both the magnitude and phase information.

Referring now to FIG. 4A, an optical quadrature interferometer 260 is shown. This optical quadrature interferometer is similar to the one shown in FIG. 4 except that polarizer 140 has been replaced with polarizing beamsplitter 65, and a dual channel imaging system 75 and 75' is implemented to provide interpretation of the data using both the phase and magnitude information. Resultant beam 86 is directed to polarizing beamsplitter 65 which provides for two polarized output beams 87 and 88. Each polarized output beam 87 and 88 is provided to a respective imaging system 75 and 75'.

Additional embodiments may include the use of any type of laser as the light source 20; a light source 20 having a short coherence length, such as a light emitting diode (LED); a superluminescent diode; a dye laser; a gas-discharge lamp; a tungsten filament lamp; a mercury arc lamp or similar type light source. A collimator or focussing system may be installed within the interferometer to change the intensity of the light beam. The imaging system 75 may include any type of imaging system, including photographic film and an optical reconstruction system to produce a holographic image of the medium being measured. In an alternate embodiment the image may be recovered by an imaging system utilizing diffraction tomography. Power reducing filters may be implemented in either arm of the interferometer when using cameras of limited irradiance resolution, such as 8-bit CCD cameras, as part of the imaging system.

By use of polarization in the optical quadrature interferometer to obtain the in-phase and quadrature information, the interferometry is more accurate and does not require phase retrieval algorithms. Additionally, the optical quadrature interferometer can be utilized in performing optical coherence tomography faster and at less expense, and holograms can be produced without ghost images. The optical quadrature interferometer may be used in applications such as non-destructive testing of optical fibers; transillumination imaging through turbid media, medical imaging through tissue such as performing mammography at optical wavelengths; and for vibration analysis.

A further embodiment, shown in FIGS. 5 and 5A, provides additional features. In this embodiment an image of an object can be acquired without a lens. The complex signal, at the CCD plane, may be back-propagated to an arbitrary plane by the Fresnel-Kirchoff Integral to produce an image of a slice of the object at that distance. The process may be repeated an arbitrary number of times using different distances to provide a set of images equivalent to those obtained in a conventional imaging system by varying the focus mechanically. This results in shorter measurement time and reduced exposure of the target to light, as all the data are collected simultaneously. This is important for example, in imaging of transient phenomena and in biological imaging.

A scanning confocal laser microscope provides useful information about diffusive media such as biological tissue by focussing a source and receiver at a common point. In the present invention, one pixel of the CCD is equivalent to the receiver in the scanning confocal laser microscope, and the other pixels provide additional information, making it possible to provide more quantitative information about the object and reducing the need for multiple views.

As shown in FIG. 2, the target 90 maybe removed and a reference picture taken. In the absence of aberrations or misalignment, no fringes will be seen. Thus, the fringes which are present are the result of an imperfect system. Taking an image with the object in place, and dividing the complex amplitude at each pixel in this image by that in the same pixel of the reference image, the effect of the object alone maybe determined. Thus, low-quality optics may be used in the system without degrading the image. This concept also works in the configuration shown in FIG. 4.

In the configuration of FIG. 4A, the output from 75 is subtracted from 76, pixel-by-pixel, and the output from 75' is subtracted from 76', with the result multiplied by the square root of negative one, resulting in a complex image with common mode noise and the non-interferometric part of the image both being rejected. Appropriate filters in hardware or scale factors in software may be required to make all signals equal in strength, i.e. to compensate for unequal beamsplitting. Furthermore, it is possible to arrange the beams as shown in FIG. 5 so that they are incident on different quadrants of a single CCD.

The configuration shown in FIG. 5A, shows the same situation with a modified Mach-Zehnder interferometer providing the same capability as in FIG. 4, but for reflective targets.

Referring now to FIG. 5 a further implementation of an optical quadrature interferometer 300 is shown. The optical quadrature interferometer 300 comprises a light source 20, such as a laser, providing a beam of light 80 which is directed to a beamsplitter 30. When a light source 20 which is not well polarized is used, a polarizer 150 which polarizes the light at 45° to the vertical, may be inserted between the light source 20 and the beamsplitter 30. Other angles are also possible, provided that a corresponding change is made at the output. If a well polarized light source is used, polarizer 150 is not necessary. The beamsplitter 30 splits the beam of light 80 into two secondary beams 82 and 84 which are in phase with each other. The beamsplitter 30 is angled such that a portion of the beam 84 is reflected along a different axis than that of beam 80, and a portion of the beam 82 passes through the beamsplitter 30.

The portion of light reflected by beamsplitter 30 is the second secondary light beam 84. This beam is directed through a quarter wave plate 120 by second reflective element 50. The quarter wave plate 120 provides for a relative phase shift of Δφ=π/2 radians which is equivalent to a phase shift of 90° between horizontal and vertical components of phase shifted beam 81.

The first secondary beam 82 is directed to a target 90 which alters the phase of light beam 82 resulting in measurement beam 85 which is directed to first reflective element 40. First reflective element 40 is angled to reflect the measurement beam 85 to an recombining beamsplitter 60.

Measurement beam 85 and phase shifted beam 81 are combined by recombining beamsplitter 60 to provide first resultant beam 86 and second resultant beam 87. First resultant beam 86 is directed through first polarizing beamsplitter 65. Polarizing beamsplitter 65 is used to separate resultant beam 86 into two separate beams 67 and 68. The beams 67 and 68 resulting from polarizing beamspllitter 65 are directed to an imaging system (not shown) which utilizes an image processing algorithm to provide interpretation of the data. Second polarizing beamsplitter 66 is used to separate the second resultant beam 87 into two separate beams 61 and 62. The beams 61 and 62 resulting from second polarizing beamsplitter 66 are directed to the imaging system (not shown) which utilizes an image processing algorithm to provide interpretation of the data.

Referring now to FIG. 5A, a further embodiment of an optical quadrature interferometer 350 is shown. This optical quadrature interferometer is similar to the one shown in FIG. 5 except that only the light reflected by the target 90 is recombined with the reference beam 81.

Considerable simplification of the processing and reduced processing time can be realized by using both outputs of the interferometer. The use of both outputs as a double balanced system is used for common mode rejection. The phase of the signal relative to the reference differs by 180 degrees between the two outputs, so the difference between the two outputs is:

    |E.sub.sig +E.sub.ref |.sup.2 -|E.sub.sig -E.sub.ref |.sup.2 =4RE*.sub.sig E*.sub.ref.

The above equation assumes each path has an equal amplitude, so some attenuation may be required in one path in order to provide the equal amplitude. The I and Q phases are needed on both outputs, and can be obtained as shown in FIGS. 5 and 5A. Each of the four outputs may be directed to a separate imaging device or to different parts of a single array.

Having described preferred embodiments of the invention it will now become apparent to those of ordinary skill in the art that other embodiments incorporating these concepts may be used. Accordingly, it is submitted that the invention should not be limited to the described embodiments but rather should be limited only by the spirit and scope of the appended claims. 

We claim:
 1. An optical quadrature interferometer comprising:a light source providing a beam of light; a first beamsplitter oriented at an angle with respect to said light source, said first beamsplitter receiving said beam of light and splitting said beam of light into a first secondary light beam and a second secondary light beam; a recombining beamsplitter; a first reflective element oriented such that said first reflective element receives said first secondary light beam and reflects said first secondary light beam along a different axis to said recombining beamsplitter; a second reflective element receiving said secondary light beam and oriented to direct said secondary light beam along a different axis; a quarter wave plate receiving said second secondary light beam from said second reflective element, said quarter wave plate providing a 90° phase shift between vertically and horizontally polarized components of the beam resulting in a circularly polarized light beam; a target receiving said circularly polarized light beam, said target causing a change to said circularly polarized light beam resulting in a measurement light beam; said recombining beamsplitter combining said measurement light beam with said first secondary light beam to provide a first resultant light beam and a second resultant light beam, said first secondary light beam having approximately the same frequency as said beam of light; a first polarizing beamsplitter receiving said first resultant light beam and splitting said first resultant light beam into a first secondary resultant light beam and a second secondary resultant light beam; a second polarizing beamsplitter receiving said second resultant light beam and splitting said second resultant light beam into a third secondary resultant light beam and a fourth secondary resultant light beam; and at least one imaging system for displaying data from said first secondary resultant light beam, said second secondary resultant light beam, said third secondary resultant light beam, and said fourth secondary resultant light beam.
 2. The optical quadrature interferometer of claim 1 wherein the change to said circularly polarized light beam by said target comprises a phase shift.
 3. The optical quadrature interferometer of claim 1 wherein the change to said circularly polarized light beam by said target comprises a change in amplitude.
 4. The optical quadrature interferometer of claim 1 wherein said imaging system comprises a scattering screen followed by a charge coupled device camera and a computer.
 5. The optical quadrature interferometer of claim 1 wherein said imaging system comprises photographic film and an optical reconstruction system.
 6. The optical quadrature interferometer of claim 1 wherein said light source comprises a laser.
 7. The optical quadrature interferometer of claim 1 wherein said light source comprises a light source having a short coherence length.
 8. The optical quadrature interferometer of claim 6 wherein said light source having a short coherence length is chosen from a group comprising a light emitting diode, a superluminescent diode, a dye laser, a gas discharge lamp, a tungsten filament lamp, and a mercury arc lamp.
 9. The optical quadrature interferometer of claim 1 wherein said at least one imaging system comprises a first imaging system for displaying data from said first secondary resultant light beam; a second imaging system for displaying data from said second secondary resultant light beam; a third imaging system for displaying data from said third secondary resultant light beam; and a fourth imaging system for displaying data from said fourth secondary resultant light beam.
 10. An optical quadrature interferometer comprising:a light source providing a beam of light; a first beamsplitter oriented at an angle with respect to said light source, said first beamsplitter receiving said beam of light and splitting said beam of light into a first secondary light beam and a second secondary light beam; a recombining beamsplitter; a first reflective element oriented such that said first reflective element receives said first secondary light beam and reflects a portion of said first secondary light beam along a different axis to said recombining beamsplitter; a second reflective element receiving said secondary light beam and oriented to direct said secondary light beam along a different axis; a quarter wave plate receiving said second secondary light beam from said second reflective element, said quarter wave plate providing a 90° phase shift between vertically and horizontally polarized components of the beam resulting in a circularly polarized light beam; a target receiving said a portion of the first secondary light beam not reflected by said first reflective element, said target causing a change to the portion of the first secondary light beam received by said target resulting in a measurement light beam; said recombining beamsplitter combining said measurement light beam with said first secondary light beam to provide a first resultant light beam and a second resultant light beam, said first secondary light beam having approximately the same frequency as said beam of light; a first polarizing beamsplitter receiving said first resultant light beam and splitting said first resultant light beam into a first secondary resultant light beam and a second secondary resultant light beam; a second polarizing beamsplitter receiving said second resultant light beam and splitting said second resultant light beam into a third secondary resultant light beam and a fourth secondary resultant light beam; and at least one imaging system for displaying data from said first secondary resultant light beam, said second secondary resultant light beam, said third secondary resultant light beam, and said fourth secondary resultant light beam.
 11. The optical quadrature interferometer of claim 10 wherein the change to said circularly polarized light beam by said target comprises a phase shift.
 12. The optical quadrature interferometer of claim 10 wherein the change to said circularly polarized light beam by said target comprises a change in amplitude.
 13. The optical quadrature interferometer of claim 10 wherein said imaging system comprises a scattering screen followed by a charge coupled device camera and a computer.
 14. The optical quadrature interferometer of claim 10 wherein said imaging system comprises photographic film and an optical reconstruction system.
 15. The optical quadrature interferometer of claim 10 wherein said light source comprises a laser.
 16. The optical quadrature interferometer of claim 10 wherein said light source comprises a light source having a short coherence length.
 17. The optical quadrature interferometer of claim 16 wherein said light source having a short coherence length is chosen from a group comprising a light emitting diode, a superluminescent diode, a dye laser, a gas discharge lamp, a tungsten filament lamp, and a mercury arc lamp.
 18. The optical quadrature interferometer of claim 10 wherein said at least one imaging system comprises a first imaging system for displaying data from said first secondary resultant light beam; a second imaging system for displaying data from said second secondary resultant light beam; a third imaging system for displaying data from said third secondary resultant light beam; and a fourth imaging system for displaying data from said fourth secondary resultant light beam. 